DE1966240C - Method for recording line drawings on the screen of an electron beam tube while keeping the resulting deflection speed of the recording electron beam constant and circuitry for carrying out the method excreted from 193 6051 - Google Patents

Description

regulated voltage values at the outputs of the. The symbols have a grid structure. the

Control amplifiers (3 and 4) sawtooth generators 25 E) at the symbols are under certain addresses

(.5 and 16) control which files are stored in memory for the deflection. You control when you call this

the starting points stream additional streams address through the computer recording the address

for the horizontal and vertical deflection of the symbols on the screen.

Line pieces deliver, and that the flow of on- Often one not only wants symbols, but also

drawing electron beam kept constant. 30 so-called "line drawings" are recorded

will. from lines of the same line width and any

2 The method according to claim 1, characterized in the form of existing drawings. As an example, one draws that a weather map that evaluates the distance, neighboring points, in addition to the symbols and meteorological on the line of lines, also lines of lines of various for-crossing one (or more) given values, such as coast and iso-lines contains. Devices, limit values the amplifiers for horizontal and which record weather maps, are so-called vertical deflection of the electron beam as well as "plotters". Even with -vissen: business computers the intensity of the beam current from fixed calculations often result in functions, which set values to second (or several) new fixed values, expediently set directly with the help of the plotter, so that one (or 40 visible as curves recorded and several) new constant deflection speed can be photographically fixed for evaluation,
and intensity of the electron beam. Such curves are displayed on

3. Circuitry to carry out the known simple way by adding rows of dots

Method characterized by two to which are recorded closely side by side, so that the

Differential voltages connected control amplifiers 45 eye a continuous closed line

ker (3, 4), two each perceives the control amplifiers (3, 4). However, this type of recording has

downstream, the square of the output voltage has the disadvantage that a lot of points are recorded

tion of the control amplifier (3, 4) forming radio must be. Each point must be separated by an X and

tion amplifier (7, 8), be determined by a K-coordinate at the outputs, which in many individual

the function amplifier (7, 8) as well as a rule calculation 50 can be determined and possibly saved

bare, the square of the target deflection speed.

The voltage emulating the electron beam is used to reduce this large amount of data

source (13) connected adder (H), which is connected to one in an improved recording method

the control inputs of the control amplifiers (3, 4) place dots with small lines with fixed lengths,

is tied, through to the outputs (5, 6) of the rule 55 Mau attaches a certain number of line units

amplifier (3, 4) connected sawtooth generator with different angles of inclination. By arrival

gates (15, 16) and through with the sawtooth rows of many of these lines corresponding

gates (15, 16) and with deflection coils (21) of the Elek inclination in any sequence and amount is approximation

electron beam tube (22) connected adder (19, attainable on the predetermined curve.

20), through which the coordinates of the basic 60 You are forced to a compromise here.

Positions of the points to be recorded in relation to the

Beam deflection are addable. recorded longer, so you need little

Information and storage space, but receives one

angular, jagged and unsightly lines. Are

65 the lines however small enough to cause this disadvantage

The invention relates to a method and a scarf improve, so the increase in the same amount

processing arrangement for recording line drawing amount of the data, which "to create, to address

on the screen of an electron beam and save it.

A favorable recording method consists in defining the smallest possible number of points on the line at differently large and expediently chosen distances and connecting these points with one another by straight lines. This creates a polygon, by means of which the target curve is approximated. In order to achieve the best possible approximation, in curved sections with small radii of curvature there must be many points close to each other, in curved sections with a large curvature radius - a few points are required, and in straight sections they only need to be present at the beginning and at the end. The line drawings produced in this way appear smooth in spite of the very different points. You ^befriedigc:; with just a few points the requirements for coziness and meet the desire to use as little data and storage space as possible.

However, one important requirement is not met here The line width should be even over the entire length of the Limeiuuges, so that it is a satisfactory one Has appearance. In achieving this uniformity has a very large S (. difficulty, namely the. that because of the very large differences in the noise of the sections and the recording times no uniform illumination and thus no smooth line width is achieved.

! A circuit arrangement for a data recorder with an electron beam display tube has already become known, in which the differences between successive .v- and; ¹ values of the horizontal and vertical components can be generated using subtraction registers. These differences are fed to linear triggerable sawtooth generators in a manner known per se which, when triggered, generate a sawtooth voltage with an amplitude that is determined by the differences. In adders, voltages that represent the starting coordinates are added to these sawtooth voltages. After the addition, these signals are given appropriate amplification to the y or .v deflection coils of the cathode ray tube. The brightness control of the electron beam takes place in such a way that the differences in the horizontal and vertical components generated to control the deflection are transferred to a multi-digit register to which a sliding step counter is connected, which has a light button generator for outputting light button signals of different duration with a time graduation of the The light button, which is determined by the reading of the sliding switch counter, controls.

From this it follows that the brightness of the graphic representation with constant beam intensity is approximately the same as the speed with which the straight lines move between two successive ones Points are written, is only approximately the same in the individual cases. But this is enough for high quality Records are not taken out, as there is still a considerable residual error.

Although there is still an intensity control circuit for cathode ray tubes known that without testing works, in which between the decoder circuits driving the deflection coils and the deflection coils two amplifier stages are arranged, which are connected via resistors, their taps are led to the intensity control. Although this control circuit is simple, it is very imprecise because the Signal used for brightness control by differentiating from that used as e-functions on the critically attenuated Deflection coil applied signal has arisen.

The present invention is therefore based on the object of a method for recording line drawings to indicate on the screen of an electron beam tube, in which also with different large distances between points connected by the electron beam, a constant brightness of the electron beam is achieved. The invention achieves this in that the differential voltages Passed through a control amplifier and squared individually, that the results are added and with a voltage value which is the square of the target beam deflection speed is proportional to be compared that the voltages determined the control amplifiers are fed and regulate their transfer variables in such a way that the control loop is stable, dal) further the regulated voltage at the outputs of the control amplifiers control sawtooth generators, which the currents additional to the deflection currents of the starting points for the horizontal and vertical deflection of the line pieces, and that the current of the recording electron beam is kept constant will.

In an advantageous further development of the invention it is provided that a »point Circuit evaluating on the line if one (or more) specified ones are exceeded Limit the amplifier for horizontal and vertical deflection of the electron beam as well as the Intensity of the beam current from fixed values to second (or several) new fixed values Switches values, so that one (or more) new constant deflection speed and intensity of the Electron beam.

A circuit arrangement for implementing the invention is characterized by two differential voltages connected control amplifiers, two downstream of the control amplifiers, the Function amplifier forming the square of the output voltage of the regulating amplifiers, through one to the outputs the function amplifier as well as a controllable, the square of the target deflection speed of the electron beam emulating voltage source connected adder, which is connected to the control inputs of the Control amplifier is connected by sawtooth generators connected to the outputs of the control amplifiers and by connected to the sawtooth generators and to deflection coils of the cathode ray tube Adders through which the coordinates of the basic positions of the points to be recorded are added to the Beam deflection are addable.

The invention is illustrated below with reference to FIGS. 1 Mnd 2 explained in more detail; it shows

F i g. 1 a polygon that approximates a curve,

F i g. 2 shows a circuit arrangement for carrying out the method at the same constant speed and constant current of the electron beam at all line pieces.

Any representations are recorded on the screen of a cathode ray tube in a conventional manner by dividing an electron beam collimated to one point in two orthogonal Coordinate directions, preferably in the horizontal (.v-direction) and vertical (^ -direction),

iuisgelcnkt and thereby more or less light or also larger, through which a constant target darkness is felt. By specifying a Koorc'i speed is set,
natenpaarcs χ and y is the position of a point on F i g. 2 shows a block diagram of an electronic structure determined by the screen and by deflection currents, with the aid of which the function a) according to gcb7.w. Stresses that are assigned to these coordinates 5 forms. The circuit structure implements the sltid, controllable. function obtained by squaring a)

Shall go through a specific point on the screen

a computer or a memory controlled b) V * -? R * · / \ x * - \ - R * · Ay *.
this is done by means of the line values of the

Coordinates λ and y of the point, which are in binary io Assume that the differences .1 χ and form are offered. The number of digits in these binary numbers, Ay of the a and v coordinates of the two points, depends on the resolution between which the curve segment is to be recorded, the electron beam point has already been calculated on the screen and should be given as proportional voltages. The following Λχ and dy may be available as a practical example. These tensions numbers apply. The usable shield diameter bc- 15 reaches the fingerstick terminals 1 and 2 of the switchgear about 210 mm. so there is a square field with structure structures. First they pass without changing the side lengths of 150 mm can be used. The elec- tron has the regulators 3 and 4 and via electron beam point the lines 5 and 6 reach the function amplifiers 7 with a diameter of 0.05 mm. In each coordinate direction then and 8. which according to equation b) the Qua-3C00 positions are possible in the whole field 9 · 10 *. To form ao dratc of tensions. The output voltage specification of the position or the data technology 9 and 10 are added in the adder 11, the same common expression for "addressing" a reference point in the field delivered at the same time via the line 12 is for ν and> · one each 12-digit binary residual voltage compared and required in the course of the control number. equated with this. The reference voltage comes from

The F i g. 1 represents an arbitrary curve, as an adjustable voltage source 13 and represents that which is to be recorded on the screen. Um GröL, Γ *. The comparison between the reference manages with as little control data as possible. voltage and the sum of the two voltages supplied by the radio are a few points P ₁ , P ₁ to P _n on the curve traction amplifiers 7 and 8, selected. The distances are very different, as is generally known in reverse engineering and is so obtained that straight connecting pieces are not shown in more detail. B. be done by adding one of the two rumors with the best possible approximation to the Sollkurvc negative Voncichen to the other size, offer. The value obtained in the adder Π and at the same time

The curve piece P _x P, is due to the co-ordinates stronger differential voltage reaches over the line 14

λ,; > ·, For point P ₁ and .v ,; y _{t determined} for point P _t . 35 at the same time to the control inputs of the RegelverstSrkcr 3

Lm the connection line P ₁ P ₂ visible to be recorded and 4 and regulates this so that in the control system

nen, the electron beam must follow the path from P, to the reference voltage and the sum of the output

Pj with a finite speed and a tension of the functional amplifiers 7 and 8 one another

agreed to go through constant brightness. becomes equal, d. that is, the differential voltage becomes zero.

The way. which the ray is supposed to take is the hypo- 40 Die only itself. setting on lines 5 and 6

tenuse of the right triangle with the cathetus voltages control the sawtooth generator 15 for the

Ax and Ay, where Ax - τ, -λ, and \ y = · y _t - y \ . Horizontal and sawtooth generator 16 for the vertical

To deflect the electron beam on the straight path α such that on the lines 17 and 18

to move uniformly from P ₁ to P ₁ , tensions must arise whose differential quotient according to

the deflection voltages for both coordinates in the 45 time proportional to the control voltages at the

same time ν on .v, after x _t or from ) \ to y _{t is} equal to lines 5 and 6. These tensions arrive

change shape. With a constant current of the electron via the adders 19 and 20 to the deflection coils 21

The distance α is written evenly in light of the ray. of the electron beam tube 22 and cause a loading

The path of the electron beam from a point P ₁ to Pr Pt '* Pr-Pt to P * -rP% adjoins the path P _t -P _t. They form a line * 50 to its neighboring point P _tn . The movement is good

train that hugs the curve. So that from a basic position, evade through you

The line sent has a uniform line width, the coordinates of the point P _{t is} determined, nimlict

the individual routes must be written in the same light x (P _:) and> (P ₁ ). These coordinate values ent

"earth. One makes the admission that there are large speaking voltages across the lines £ line pieces at the same speed and 14 at the second input of the adders 19 and V

draws earths like small ones, so is for all line segments and determine the starting position for movement

also the point brightness is the same, and the total of the electron beam. The adders 19 and 20 should

Line drawing is recorded evenly. In the example shown, they are also the controlling chip

The entire recording time can be converted into deflection currents under certain circumstances. The brightness de booths be great. 60 electron beam is controllable with the help of a «

The invention is based on the knowledge that S ^ annungsqueOe 25 to a desired value

satisfy the following equation: posed, and the deflection time of each sawtooth

\ ν ο lTTZrzXi ν "". ».". phasen fet proportional to the zo writing stretcher

a) V = R ■ YΛχ «+ Ay * = constant, _Dazo ^ _{em entS} p _calculated ^ _0n , included

where V means speed, and R a rule Gs Schaher.

1 sheet of drawings

Claims (1)

Claims tube while keeping the resulting claims constant. Deflection speed of the recording electrical 1. Method for recording line drawing beams, with the coordinates of individual points On the screen one electron beam - on the lines of the drawing with different sizes tube while keeping the resulting 5 distances constant, and with straight through Deflection speed of the recording elec- electron beam, whereby the coordinates of individual drawings produced approximately the same lines Points on the lines of the drawing with and from the differences in the coordinates at large distances, and differential voltages are derived from barter points, where by straight connecting lines between io to represent calculated by computer the dots approximated to the line drawings information is often an electron beam tube the same lines were made and used from the differences. Mostly it concerns the representations delimit the coordinates of neighboring points by a limited number of symbols, that is Differential voltages are derived, because digits, letters and characters, whose characterized in that the difference 15 drawing data in an electronic memory of the Residual voltages via control amplifiers (3 and 4) on the recording device or stored in the computer led and squared individually that the results are. The data consist of binary numbers of the added and with a voltage quantity which corresponds to the coordinates for the positioning on the screen Square a? R beam deflection target speed pro- and from binary coded numbers as an indication of the is proportional to be compared that the determined 20 lengths of the individual image lines, from which the Voltages in the control amplifiers (3 and 4) trains symbols are built up. Every image line piece is off and their transmission quantities are built up to a whole multiple of a small piece, regulate that the control loop is stable, that its size at the limit of perception of the eye